#!/usr/bin/env python3
# ----------------------------------------------------------------
# Programmer(s): Daniel R. Reynolds @ SMU
# ----------------------------------------------------------------
# SUNDIALS Copyright Start
# Copyright (c) 2002-2025, Lawrence Livermore National Security
# and Southern Methodist University.
# All rights reserved.
#
# See the top-level LICENSE and NOTICE files for details.
#
# SPDX-License-Identifier: BSD-3-Clause
# SUNDIALS Copyright End
# ----------------------------------------------------------------
# matplotlib-based plotting script
# ----------------------------------------------------------------

# imports
import glob
import sys
import pylab as plt
import numpy as np

# load mesh data file
mesh = np.loadtxt("mesh.txt", dtype=np.double)

# load output time file
times = np.loadtxt("t.000000.txt", dtype=np.double)

# load solution data files
ufiles = glob.glob("u." + ("[0-9]" * 6) + ".txt")
ufiles.sort()
vfiles = glob.glob("v." + ("[0-9]" * 6) + ".txt")
vfiles.sort()
wfiles = glob.glob("w." + ("[0-9]" * 6) + ".txt")
wfiles.sort()
udata = np.loadtxt(ufiles[0], dtype=np.double)
vdata = np.loadtxt(vfiles[0], dtype=np.double)
wdata = np.loadtxt(wfiles[0], dtype=np.double)
for idx in range(1, len(ufiles)):
    udata = np.hstack((udata, np.loadtxt(ufiles[idx], dtype=np.double)))
    vdata = np.hstack((vdata, np.loadtxt(vfiles[idx], dtype=np.double)))
    wdata = np.hstack((wdata, np.loadtxt(wfiles[idx], dtype=np.double)))

# determine number of time steps, mesh size
nt, nx = np.shape(udata)

# determine min/max values
umin = 0.9 * udata.min()
umax = 1.1 * udata.max()
vmin = 0.9 * vdata.min()
vmax = 1.1 * vdata.max()
wmin = 0.9 * wdata.min()
wmax = 1.1 * wdata.max()
xmax = mesh.max()
minval = np.array([umin, vmin, wmin]).min()
maxval = np.array([umax, vmax, wmax]).max()

# generate plots of results
for tstep in range(nt):

    # set string constants for output plots, current time, mesh size
    pname = "solution." + repr(tstep).zfill(3) + ".png"
    tstr = repr(tstep)
    nxstr = repr(nx)

    # plot current solution and save to disk
    plt.figure(1)
    plt.plot(mesh, udata[tstep, :], label="u")
    plt.plot(mesh, vdata[tstep, :], label="v")
    plt.plot(mesh, wdata[tstep, :], label="w")
    plt.xlabel("x")
    plt.ylabel("solution")
    plt.title("Solutions at output " + tstr + ", mesh = " + nxstr)
    plt.axis((0.0, xmax, minval, maxval))
    plt.grid()
    plt.legend(loc="upper right", shadow=True)
    plt.savefig(pname)
    plt.close()

# set string constants for output plots, current time, mesh size
pname = "solution_at_x0.png"
xstr = repr(mesh[0])

# plot current solution and save to disk
plt.figure(1)
plt.plot(times, udata[:, 0], label="u")
plt.plot(times, vdata[:, 0], label="v")
plt.plot(times, wdata[:, 0], label="w")
plt.xlabel("t")
plt.ylabel("solution")
plt.title("Solutions at output at x = " + xstr)
plt.axis((times[0], times[-1], minval, maxval))
plt.grid()
plt.legend(loc="upper right", shadow=True)
plt.savefig(pname)
plt.close()


##### end of script #####
